Food processing apparatus and method

ABSTRACT

Food processing apparatus and methods for processing food are disclosed. The apparatus may include stored sequences for operating a processing tool. The stored sequences may address various challenging aspects of blending solid foods and/or ice. In some embodiments, particular sequences are implemented with specific processing tools.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. Non-Provisional applicationSer. No. 15/579,856 filed Dec. 5, 2017, which is a National Stageapplication of PCT/US2016/036377, filed Jun. 8, 2016, which claims thebenefit of U.S. Provisional Application No. 62/172,678, filed Jun. 8,2015, all of which are incorporated by reference in their entiretyherein.

FIELD

Aspects herein generally relate to a food processing apparatus and to amethod of processing food using a food processing apparatus. Morespecifically, aspects disclosed herein relate to a food processingapparatus having stored sequences that can be used to prepare variousfoods in an effective and convenient manner.

DISCUSSION OF RELATED ART

Blenders and other food processors are typically used to chop, blend,mix, or pulverize food, crush ice, mix liquids, and blend liquid andsolid food together using blades or other processing tools. Typically,the processing tools are rotated at various speeds within a container.

SUMMARY

According to one illustrative embodiment, a food processing apparatusincludes a container including at least one rotatable, sharp blade, adrive unit having a drive coupler to rotate the at least one blade, anda controller to control the drive unit. The apparatus also includes atleast one non-transitory memory storing processor-executableinstructions that, when executed by the controller, cause thecontroller, in response to a first user input, to sequentially: activatethe drive unit for three seconds or less to rotate the drive coupler asa first pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa second pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa first blending segment; pause the drive unit for at least one second;activate the drive unit for at least five seconds to rotate the drivecoupler as a second blending segment; pause the drive unit for at leastone second; and activate the drive unit for at least five seconds torotate the drive coupler as a third blending segment. A total timeperiod of all activations of the drive unit that are at least fiveseconds for blending segments is at least twenty-three seconds.

According to yet one illustrative embodiment, a food processingapparatus includes a container including at least one rotatable, sharpblade, a drive unit having a drive coupler to rotate the at least oneblade, and a controller to control the drive unit. The apparatus alsoincludes at least one non-transitory memory storing processor-executableinstructions that, when executed by the controller, cause thecontroller, in response to a first user input, to sequentially: activatethe drive. unit for three seconds or less to rotate the drive coupler asa first pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa second pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa third pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa first blending segment; pause the drive unit for at least one second;and activate the drive unit for at least five seconds to rotate thedrive coupler as a second blending segment. A total time period of allactivations of the drive unit that are at least five seconds forblending segments is at least nineteen seconds.

According to still one illustrative embodiment, a food processingapparatus includes a container including at least one rotatable, sharpblade, a drive unit having a drive coupler to rotate the at least oneblade, and a controller to control the drive unit. The apparatus alsoincludes at least one non-transitory memory storing processor-executableinstructions that, when executed by the controller, cause thecontroller, in response to a first user input, to sequentially: activatethe drive unit for three seconds or less to rotate the drive coupler asa first pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa second pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa first blending segment; pause the drive unit for at least one second;activate the drive unit for three seconds or less to rotate the drivecoupler as a third pulse; pause the drive unit for at least one second;activate the drive unit for at least five seconds to rotate the drivecoupler as a second blending segment; pause the drive unit for at leastone second; and activate the drive unit for at least five seconds torotate the drive coupler as a third blending segment. A total timeperiod of all activations of the drive unit that are at least fiveseconds for blending segments is at least fifty-two seconds.

According to still one illustrative embodiment, a food processingapparatus includes a container including at least one rotatable, sharpblade, a drive unit having a drive coupler to rotate the at least oneblade, and a controller to control the drive unit. The apparatus alsoincludes at least one non-transitory memory storing processor-executableinstructions that, when executed by the controller, cause thecontroller, in response to a first user input, to sequentially: activatethe drive unit for three seconds or less to rotate the drive coupler asa first pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa second pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa third pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa first blending segment; pause the drive unit for at least one second;activate the drive unit for three seconds or less to rotate the drivecoupler as a fourth pulse; pause the drive unit for at least one second;activate the drive unit for three seconds or less to rotate the drivecoupler as a fifth pulse; pause the drive unit for at least one second;activate the drive unit for at least five seconds to rotate the drivecoupler as a second blending segment; pause the drive unit for at leastone second; and activate the drive unit for at least five seconds torotate the drive coupler as a third blending segment. A total timeperiod of all activations of the drive unit that are at least fiveseconds for blending segments is at least forty-seven seconds.

According to another illustrative embodiment, a method is used inconnection with operation of a food processing apparatus, the apparatuscomprising a drive unit to drive a food processing assembly, acontroller to control the drive unit, and at least one non-transitorymemory storing processor-executable instructions that are executable bythe controller to cause the controller to control the drive unit. Themethod includes, in response to a first user input, sequentially:activating the drive unit for three seconds or less to rotate the drivecoupler as a first pulse; pausing the drive unit for at least onesecond; activating the drive unit for three seconds or less to rotatethe drive coupler as a second pulse; pausing the drive unit for at leastone second; activating the drive unit for at least five seconds torotate the drive coupler as a first blending segment; pausing the driveunit for at least one second; activating the drive unit for at leastfive seconds to rotate the drive coupler as a second blending segment;pausing the drive unit for at least one second; and activating the driveunit for at least five seconds to rotate the drive coupler as a thirdblending segment. A total time period of activating of the drive unitthat are at least five seconds for blending segments is at leasttwenty-three seconds.

It should be appreciated that the foregoing concepts, and additionalconcepts discussed below, may be arranged in any suitable combination,as the present disclosure is not limited in this respect.

The foregoing and other aspects, embodiments, and features of thepresent teachings can be more fully understood from the followingdescription in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are not intended to be drawn to scale. In thedrawings, each identical or nearly identical component that isillustrated in various figures is represented by a like numeral. Forpurposes of clarity, not every component may be labeled in everydrawing. Various embodiments of the invention will now be described, byway of example, with reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of a blender base in accordance with oneaspect; FIG. 2 is a perspective view of a blender base in accordancewith one aspect;

FIG. 3 is a perspective view of a container with an attached bladeassembly in accordance with one aspect;

FIG. 4 is a perspective view of the container of FIG. 3 attached to ablender base in accordance with one aspect;

FIG. 5 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 6 is a flow chart of an illustrative food processing sequence inaccordance with one

FIG. 7 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 8 is a flow chart of an illustrative food processing sequence inaccordance with one

FIG. 9 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 10 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 11A is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 11B is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 12 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 13 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 14 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 15 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 16 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 17 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 18 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 19 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 20 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 21 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 22 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 23 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 24 is a flow chart of an illustrative food processing sequence inaccordance with

FIG. 25 is a flow chart of an illustrative food processing sequence inaccordance with one aspect;

FIG. 26 is a flow chart of an illustrative food processing sequence inaccordance with one

FIG. 27 is a flow chart of an illustrative food processing algorithm inaccordance with one

FIG. 28 is a top view of a blender base in accordance with one aspect;

FIG. 29 is a top perspective view of a set of blades in accordance withone aspect;

FIG. 30 is a bottom perspective view of a set of blades in accordancewith one aspect;

FIG. 31 is a perspective view of container attached to a blender base inaccordance with one aspect;

FIG. 32 is a side view of a container in accordance with one aspect;

FIG. 33 is a perspective view of container attached to a blender base inaccordance with one aspect; and

FIG. 34 is a block diagram of an illustrative controller that may beused in implementing some embodiments.

DETAILED DESCRIPTION

Food processors, such as a blender, typically include a processing tool,such as a blade or blades, within a container, and an electric motorwhich rotates the processing tool via a drive coupling. Some foodprocessors include a programmed controller which allows a user to selecta specific, stored sequence of motor operation to rotate the blades. Theinventors have appreciated that existing sequences have limitations,especially when attempting to process low liquid and/or fibrous foodswith minimal or no user intervention.

According to aspects of embodiments disclosed herein, a processingsequence is particularly suited to processing food mixtures whichinclude solid components. For example, a processing sequence includes ashort run of a blade or blades to initially chop food and/or break downfibers, skins, seeds, and/or ice. After at least one pause to allow thefood to fall toward the bottom of the container and/or toward the bladepath, the sequence proceeds to a continuous processing time segment ofat least five seconds to crush and/or start liquefying the ingredients.At least another pause follows, and then a further continuous segment ofat least five seconds to liquefy the contents of the container. By usingsuch a sequence, smooth liquids may consistently be created even whenblending ingredients which are difficult to liquefy. In someembodiments, the breakdown of fibrous ingredients helps to create adrink which has a smooth consistency and includes extracted nutrients.Longer times may be used in some embodiments. For example, in someembodiments, the total processing time of the longer blending segmentsmay be at least twenty seconds. In some embodiments, the pause segmentsinclude a stoppage of the blade, while in other embodiments, the pauseembodiments include the blade slowing to an rpm of 100 rpm or less.

According to another aspect of embodiments disclosed herein, a foodprocessing apparatus is programmed to include an act of causing blendedcomponents to move along an inner side wall of the blender containerupwardly toward the upper end of the blender container, to removeingredients that may be caught on the inner wall of the container, oreven on the underside of a lid of the container. In this manner,ingredients stuck on the inner side wall and/or lid may be returned tothe blended mixture and processed with the blades.

For example, when processing foods, especially leafy greens or otherfoods with a high ratio of surface area to weight, food portions may bepropelled toward the upper end of the container and stick to the innerwalls, especially during the early stages of a sequence when solid foodhas not yet been chopped into small pieces. According to embodimentsherein, after sufficient blending has occurred to at least partiallyliquefy the contents within the container, the blades or otherprocessing tool may be stopped or slowed to a speed at which the liquidslows down and is substantially level within the container. The bladesthen may be quickly accelerated to drive the liquid outwardly andupwardly along the inner walls of the container. The liquid contacts theitems caught on the container walls and dislodges them so that they fallback into the mixture being blended. In some embodiments, the motor isinstantaneously powered with full power to accelerate the blades.

The inventors have appreciated that in certain circumstances, providingcontrol of one or more specific parameters to a user during theoperation of a program can permit improved food processing results.

For example, according to one embodiment disclosed herein, a programmedfood processing sequence includes a series of on/off pulses. That is,the blades are driven for an amount of time, then stopped for an amountof time, again driven for an amount of time, and then stopped. Thissequence may be repeated any suitable number of times and can be helpfulfor initially chopping solid food ingredients, and then letting theingredients move toward the bottom of the container and/or toward thehorizontal center of the container while the blades are stopped. In thismanner, when the blades are restarted, more of the ingredients arewithin reach of the blades and/or in an area where they will be drawntoward the blades. According to embodiments herein, while the amount oftime that the one or more blades (or other processing tool) are drivenis set by the program and not alterable by the user during operation,the user is able to choose a suitable amount of time for each “off’ timeperiod while operating the blender. This particular arrangement isunlike typical programmed blenders which have preset amounts of time forboth the “on” periods and the and “off’ periods which the user cannotmodify during operation.

The inventors have appreciated that when manually pulsing a blender,users often keep the motor on for too long, which can result in blendingrather than chopping or pulverizing. The inventors have also appreciatedthat programming a blender controller with a suitably long pulsesequence to accommodate a range of ingredient mixtures can lead to “off’time periods which are unnecessarily long in some circumstances. Incertain embodiments disclosed herein, a programmed pulse sequenceincludes preset “on” times, followed by a default “off’ time which auser can shorten in any suitable manner, for example by letting go of abutton and then re-pressing the button. A second, preset “on” timefollows the “off’ time. In this manner, the programmed blender canprevent overly long “on” times while also avoiding overly long “off’times.

According to another aspect of the disclosure, processing sequencesparticularly suited for pureeing foods are disclosed herein. Accordingto one embodiment, a blender starts a sequence by reaching asteady-state low rotational blade speed, and after at least five secondsat the low speed, increases to a steady-state medium rotational bladespeed, and after at least five seconds at the medium speed, increases toa steady-state high speed. In some embodiments, the high speed continuesfor an amount of time that is longer than the low speed and medium speedtimes combined. Such a sequence provides initial segments which breakdown ingredients such that during the high speed segment, cavitation canbe avoided while running at a speed that efficiently creates a smoothtexture.

In some embodiments, the progression of speeds for pureeing is performedin conjunction with a set of stacked blender blades which each have asubstantially flat arrangement and a curved leading edge. The sequencemay be configured such that the blade speed does not fall below anyprior steady-state blade speed until the end of the steady-state highblade speed time period.

Particular stored sequences may be indicated as being available for usevia indicators associated with stored sequence buttons. In someembodiments, particular stored sequences may be useable only with one ormore types of containers. To indicate the availability of storedsequences for a particular container attached at a given time, the foodprocessor may be configured to determine which type of container isattached, and a visual cue may be provided to the user as to whichstored sequence(s) may be used. For example, in one embodiment, acontroller illuminates a light associated with a specific button toindicate that the stored sequence (or other functionality) correspondingto that button (or other input) may be used. The button may have aparticular sequence name or functionality name printed on or near thebutton.

According to another aspect of embodiments disclosed herein, a samebutton, or other input, may be used to initiate different storedsequences depending on what type of container is attached to the foodprocessing apparatus.

Control Panel

FIG. 1 shows one embodiment of a blender base 100 with a control panel102 and a container interface 104 for attaching a container to the base.The blender base 100 includes a drive unit (not shown), such as anelectric motor and a drive coupler which can be mated to a drivencoupler on an attached container. A controller (not shown in FIG. 1) isincluded for controlling the drive unit, in some cases to execute storedsequences of motor operation.

The control panel includes a number of buttons 106, 108, 110, 112, 114,116, 118, 120, and 122 in the illustrated embodiment, though anysuitable structure for receiving user input may be utilized. Button 106is an on/off button which allows the user to activate or deactivate thecontrol panel. When the control panel is deactivated, the motor is notpowered.

Button 108 activates the motor to run at a “low” speed by supplying acertain amount of power to the electric motor. The actual speed of themotor and hence the speed of the blades or other processing tool mayvary based on the type and consistency of food within the container. Insome embodiments, a feedback control may be provided which senses thespeed of the motor or other components and adjusts the electric power tomaintain a certain speed or speed profile. In some embodiments, forexample, in personal serving containers, a target motor rotational speedof approximately 7,000 rpm is activated by the button 108 with thecontainer substantially full of liquefied food. Similarly, button 110activates a medium speed, which may be an approximate target rotationalspeed of 9,000 rpm in some embodiments with the container substantiallyfull of liquefied food. Button 112 activates a high speed, which may bean approximate target rotational speed of 11,000 rpm in some embodimentswith the container substantially full of liquefied food.

Buttons 114, 116, 118, 120 activate stored sequences according toembodiments disclosed herein. In some cases, a stored sequence isdesigned to be particularly well suited for a class of food preparationand/or particular ingredients or types of ingredients. The particularstored sequence that is activated by a given button may vary dependingon the type of container that is attached to the blender base so thatthe food preparation may be enhanced further.

For example, in the illustrated embodiment, button 114 activates asequence of motor control which rotates a set of blades to producefrozen drinks having a high degree of ice pulverization in an efficientmanner. The particular sequence may vary depending on the size and/ortype of container attached to the blender base. Button 116 invokes asequence particularly well suited for preparing purees, as describedfurther below with reference to FIGS. 8, 9 and 10. Button 120 allows auser to select a stored sequence which targets the processing of frozenfood items. A stored sequence aimed at blending fresh foods is activatedwith button 118. In some embodiments, by pressing a single button once,a user can process foods that might typically require user intervention.

Button 122 activates a pulse sequence, which in some embodiments maypermit a user to alter the sequence while the blender is operatingaccording to the pulse sequence. For example, in some embodiments, thebutton 122 may be used to activate a series of pulses where the motor ison for a set amount of time, but the length of time that the motor isoff is adjustable by the user while pulsing.

Sequence Indicators

One or more of the buttons may include a light or other indicator toshow that the respective button will initiate a function if actuated.For example, a light 130 may be illuminated on button 114 indicatingthat the frozen drinks sequence available for operation. If pressingbutton 114 will not result in motor activation, light 130 will not beilluminated. The illumination status of light 130 may be based on thetype of container attached to the blender base or any other suitableparameter. For example, the food processing apparatus may include aweight sensor and/or a temperature sensor, and the availability of agiven sequence or other function may be based on the measurementsreceived from one or both sensors.

Personal Serving Embodiment

FIG. 2 shows another embodiment of a blender base 200 having a containerinterface 201 and a control panel 202 with a different arrangement ofbuttons as compared to the embodiment of FIG. 1. Blender base 200 may beused with a personal serving container as shown by way of example inFIG. 3. A button 204 may be used to start and stop the motor. A button206 is used to initiate a pulse sequence, which in some embodimentspermits a user to alter a length of a pauses between motor activations.A button 208 may be used to start a sequence directed at processingfrozen food items. Fresh food items may be processed using a storedsequence initiated by a button 210.

Other arrangements of buttons or other inputs may be used with any ofthe various embodiments disclosed herein. For example, dials, flipswitches, rotary knobs, slide knobs, voice-activated commands, virtualkeyboards, or any other suitable input may be used.

Motor

The motor contained within blender base 200 of FIG. 2 may be rated at1,000 watts in some embodiments, though any suitable motor may be used.In some embodiments, the motor may be run at full power, while in otherembodiments, the motor may be run at less than full power, even when ona “high” setting. The motor may be configured to run at approximately20,000 RPM when unloaded. In some embodiments, the motor can be run withdifferent power inputs for different sequences or run at different powerinputs within a single sequence. In other embodiments, the motor is runwith the same power input for all stored sequences.

The motor contained within blender base 100 of FIG. 1 may be rated at1,500 watts in some embodiments, though any suitable motor may be used.The motor may be run at least than full power at times. For example, themotor may be run at 85% of full power, or any other suitable percent ofpower in some embodiments, when being operated with the personal servingcontainer shown in FIG. 3 and a “high” setting is selected by the useror is part of a stored sequence. See FIG. 24 for one embodiment of apersonal serving container mounted to the base of FIG. 1. With a 1,500watt motor, the 85% power input results in a rotation speed ofapproximately 21,500 rpm when unloaded. For medium settings, the motormay be supplied with 80% power input, resulting in a rotation speed ofapproximately 20,000 rpm when unloaded. For low settings, the motor maybe supplied with 60% power input, resulting in a rotation speed ofapproximately 15,000 rpm when unloaded. When used with the containershown in FIG. 31, the motor may be run at 100% power, and rotate atapproximately 24,000 rpm when unloaded. Any suitably sized motor and/orpower input may be used in various embodiments.

For purposes herein, when a motor speed, processing tool speed, or drivecoupler speed is discussed, a constant speed is not necessarilyrequired. The speed may vary slightly over time as a result of intendedchanges to the power which is provided to the motor. Or, the speed mayvary as a result of the food contents being processed in the container.For example, in some embodiments, a motor may be supplied with 85% ofits full rated power, and the motor and blades may initially rotate at8,000 rpm under the load of the unprocessed food in the container. Asthe food is processed, the blades become easier to rotate, and the motorspeed may increase to 13,000 rpm even though the same amount of power isbeing supplied to the motor.

Personal Serving Container

FIG. 3 shows a container assembly 400 including a container 402 and acontainer base 404 which is removably attachable to the container 402with threads (not shown). Container 402 includes four equally spacedengagement members, such as tabs 406 (only two are shown in FIG. 3)which engage with slots in an associated blender base. In someembodiments, the tabs or other engagement members extends from thecontainer base 404 instead of the container 402. Container 402 may beused to prepare personal serving sizes which can be consumed directlyfrom the container.

A processing assembly, such as a shaft supporting six blades 408 a, 408b, 410 a, and 410 b is positioned within the container when thecontainer base 404 is attached to the container. A driven coupler (notshown in FIG. 3) is positioned on the underside of the container base torotate the blades when attached to a blender base.

The container assembly 400 is shown in FIG. 4 mounted to a blender base450. The blender base 450 includes a motor which rotates a drive coupler(not shown in FIG. 4), which in turn rotates the blades 408 a, 408 b,410 a, and 410 b via the driven coupler on container base 404.

Blades which are parallel to the axis of rotation, such as verticalblades 414 a, 414 b, may be included in some embodiments. Verticalblades 414 a, 414 b include upwardly facing sharp edges 414 a, 414 b insome embodiments, and these sharp edges may be slanted relative tohorizontal (or slanted relative to a plane that is perpendicular to theaxis of rotation). Vertical blades 414 a, 414 b may oriented such thatwhen rotated, the blades lead with taller side edges 416 a, 416 b. Inother embodiments, the vertical blades 414 a, 414 b may be oriented tolead with short side edges 418 a, 418 b. The upwardly facing edges maynot be sharp in some embodiments. The vertical blades 414a, 414b may beused with various blending sequences or other food processing sequencesdescribed herein. In particular, these blades may be used with sequenceswhich are particularly well suited to process ice or frozen foods.

As used herein, the term “processing tool” refers to any tool used toprocess foods and other materials. A processing tool may include, but isnot limited to, one or more blades, one or more whisks, one or more icecrushers, one or more dicers, one or more graters, one or moreshredders, one or more combined shredder/slicers, one or more cubers,one or more dough hooks, one or more whippers, one or more slicers, andone or more french fry cutters. In some cases, a processing tool may beone or more tools that are used to clean the food processor container.As used herein, the term “food” includes any solid or liquid comestible,and any mixture of a solid food and a liquid food.

While blender bases are shown and described herein as being positionedunder a container such that the base supports the container, in someembodiments, the base may comprise a drive unit which is configured tomount to the top of a container. In other words, for purposes herein, ablender base is not required to be positionable under a container or tosupport a container.

Stored Sequences

The inventors have appreciated that conventional food processingsequences do not provide desirable results when used with various foodsand food combinations. For example, with fibrous ingredients, solidfoods with a low liquid content, and/or larger pieces of solid foods,various conventional processing sequences may result in cavitation. Thatis, in some cases, with food packed into the container, the blades arerotated, and the blades manage to cut through the food that is withinthe blade path, but without liquid to move the solid ingredients,minimal further processing occurs. To address this issue, users havetypically been instructed to add liquid to the container, and/or a use apusher to periodically push unprocessed food into the blade path, buteach method has its drawbacks.

According to embodiments disclosed herein, certain processing sequencesare capable of processing foods without user intervention and withoutthe addition of extra liquids—including foods which typically have beendifficult to process without user intervention. By doing so, users maybe able to include foods in their recipes which they otherwise mightavoid only because of the processing difficulties. With the sequencesdisclosed herein, users also may be able to include the skins of foodsthat they previously tended to remove. Skins are important when tryingto include fiber and nutrients in a final, blended product.

One embodiment of a stored sequence 500 which may be used to blendfoods, and especially foods or food combinations which resist processingwith a blender, is illustrated in FIG. 5. This sequence may be used withthe personal serving container shown in FIGS. 3 and 4 along with theblades shown in the same figures, though any suitable container andprocessing tool combination may be used with this sequence.

The sequence 500 of FIG. 5 starts with two repetitions of pulse segmentsof 1.5 seconds on and two seconds off, followed by a first continuousrun segment 501 of twelve seconds. By including short “on” segments withinterspersed “off’ segments (or pause segments with slow rotations)early in the sequence, initial chopping and/or liquefaction is performedwithout resulting in cavitation. The process of accelerating the bladescan move ingredients within the container, while the “off’ segmentsallow gravity to move solids and liquids into the blade path such thatupon restart, these foods are contacted by the blades. This additionalcontact not only processes the contacted food, but also uses thecontacted food to move other food within the container. Accordingly, thepulse segments at or near the beginning of the sequence begin to liquefysome of the softer foods and move around and chop some of the harderfoods. If the blades are simply turned on and run continuously at highspeed from the start of the sequence, solid food which starts to fallinto the blade path is incrementally contacted by the blades, and theresulting small bits of food are not as good at moving other foods.

The continuous run segment 501 of twelve seconds starts processing therougher ingredients and continues processing and liquefying the softerfoods to start creating a smooth liquid.

The sequence includes an “off’ segment 502 and an immediately subsequentrapid acceleration “on” segment 504 to cause liquids and solids to surgebriefly upwardly along an inner side wall of the blender containertoward the upper end of the blender container. This portion of thesequence uses the liquefied material in the blender container torecapture ingredients that may be caught on the inner wall of thecontainer or the underside of the container lid so that the ingredientsmay be returned to the blades or other processing tool. For purposesherein, such action is referred to as a fountain effect sequence. Thefountain effect sequence is discussed in more detail further below.

Segment 504 is seven seconds long to continue processing the ingredientsfor a smooth texture. Any ingredients recaptured by the fountain effectsegments are liquefied and processed during segment 504.

Two more “off’ and rapid acceleration “on” segments follow segment 504to again attempt to recapture any foods that have become stuck on theinner walls or the lid underside. A final segment 506 runs continuouslyfor twelve seconds to achieve a final smoothness and to process anyfoods recaptured during the final fountain effect segments.

The precise times disclosed in this particular sequence are notnecessarily required, and may be varied depending on the motor power,blade speed, type of food(s) to be processed, etc. For example, in someembodiments, the first continuous run segment 501 may be at least fiveseconds, at least seven seconds, at least ten seconds, at least fifteenseconds, or any other suitable length. The second continuous run segment504 may be at least five seconds, seven seconds, ten seconds, fifteenseconds, or any other suitable length. In some embodiments, the sequencemay end after the second continuous run segment 504. Where the thirdcontinuous run segment 506 is included, it may be at least five seconds,seven seconds, ten seconds, fifteen seconds, or any other suitablelength. Additional sequential, short “on” and “off’ segments may beincluded before, between, or after the various continuous run segmentsin some embodiments. For example, in sequence 500, additional short “on”and “off’ segments may be included between immediately sequentialsegments 502 and 504, resulting in a sequence in which sequentialsegments 501 and 504 include several short “on” and “off’ segmentsbetween them.

In some embodiments of blend sequences similar to sequence 500, thetotal amount of all “on” time periods may be at least twenty-fiveseconds, at least twenty-nine seconds, at least thirty-six seconds, orany other suitable length. The total time period of the entire sequencemay be no more than fifty seconds in some embodiments, no more thanforty-five seconds in some embodiments, or limited to any other suitabletime period.

For purposes herein, the term “pause” as part of a sequence of foodprocessing apparatus operation refers both to: a) not activating thedrive unit for a period of time, and b) activating the drive unit at alevel for a period of time such that if the processing tool were toreach a steady state speed based on the average activation levelprovided to the drive unit over the period of time, the processing toolwould have a speed of 100 rpm or less. For example, a blending sequencewhich includes a 2.5 second time period during which electricity is notprovided to the motor is considered to have a 2.5 second pause segment,even though the processing tool may not immediately stop rotating whenthe motor is de-energized. As another example, a pause segment mayinclude a motor driven at 300 rpm for three seconds, which, through atransmission, results in a steady state processing tool speed of 60 rpm.Even though the processing tool does not have a speed of 60 rpm from thestart of the three second time period, the segment is still consideredto be a three second pause. As another example, for two seconds, a motormay be cyclically powered to between two power levels which results inthe drive unit and blades rotating from between 10 rpm and 20 rpm, withan average speed of 15 rpm over the two second time period. Such a timeperiod would be considered a pause for purposes herein.

Many of the sequence embodiments described and illustrated herein referto an “off’ time period. An “off’ time period, for purposes herein,means a time period during which the drive unit is not activated, thoughthe drive unit may continue to rotate during some or all of the “off’period due to residual momentum. However, anytime that an “off’ periodis referred to herein, a “pause” segment may be implemented instead. Forexample, segment 502 of FIG. 5 may be a two second pause instead of atwo second “off’ segment. As discussed above, a pause segment mayinclude slow rotations of a processing tool or may include a shut-off ofthe drive unit (such as a motor).

A sequence 600, as shown in FIG. 6, may be similar to sequence 500, butwith a shorter final continuous run segment 602 of seven seconds insteadof twelve seconds. A higher blade speed may permit the reducedcontinuous run time. In some embodiments, sequence 600 may be used withthe personal serving container similar to the container shown in FIGS. 3and 4, but with blender base 100. See, for example, FIG. 31.

Examples of foods where such sequences may be particularly beneficialinclude celery, cabbage, apples, ice, blueberries, and other fibrousfoods and/or foods with skins.

For food combinations which are particularly difficult to blend and/orwhich contain ice, a sequence 700 with a higher number of pulse segmentsmay be used. Sequence 700 includes a total of four pulses segments thathave a 1.5 second “on” time period, and a 2.5 second “off’ period. Theadditional pulse segments, as well as the increased “off’ time periodsrelative to sequences 500 and 600, provide more chopping and initialliquefaction prior to continuous run segments that are longer than tenseconds. Also included in sequence 700 is a five second “on” segment 702situated between two sets of pulse segments, which is intended to startcrushing ice and/or fibrous components. As with sequences 500 and 600,the starts and stops help to prevent cavitation, while the continuousruns later in the sequence provide the blending which leads to a smoothconsistency of the resulting product.

In some embodiments, the pulse segments include an “on” pulse of twoseconds or less, while other embodiments include pulses of 2.5 secondsor less, or three seconds or less. In some embodiments, the pulsesegments include an “on” pulse of at least 1 second, other embodimentsinclude “on” pulses of at least 1.5 seconds, and further embodimentsinclude “on” pulses of at least two seconds.

In some embodiments of blend sequences similar to sequence 700, thetotal amount of all “on” time periods may be at least thirty seconds, atleast thirty-seven seconds, at least 42.5 seconds, or any other suitablelength. The total time period of the entire sequence may be no more thanfifty seconds in some embodiments, no more than fifty-five seconds insome embodiments, no more than sixty seconds in some embodiments, nomore than sixty-five seconds in some embodiments, or may be limited toany other suitable time period.

A sequence 800, as shown in FIG. 8 may be similar to sequence 700, butinstead of a final continuous run segment of 16.5 seconds, sequence 800includes a five second continuous run segment 850, a 2.5 second “off’segment 852, an “on” pulse 854 of 1.5 seconds, an “off’ segment 856 of2.5 seconds, and a final, continuous run segment 858 of five seconds.The extra two pauses in sequence 800 as compared to sequence 700 mayprovide two additional fountain effect sequence to recapture food caughtoutside of the blended mixture. The slight decrease in the total amountof time of “on” segments may be made possible by running the blades at ahigher speed as compared to some embodiments of sequence 700. In someembodiments, sequence 800 may be used with the personal servingcontainer similar to the container shown in FIGS. 3 and 4, but withblender base 100. See, for example, FIG. 33.

A flowchart 900 in FIG. 9 of a blending sequence includes acts whichcause ingredients to surge briefly upwardly along an inner side wall ofthe blender container toward the upper end of the blender container torecapture ingredients that may be caught on the inner wall of thecontainer or the underside of the container lid. For purposes herein,such action is referred to as a fountain effect sequence.

As one example of a fountain effect sequence, after a series of pulseswhere the motor is on for an amount of time, and then off (or otherwisepaused) for 2.5 seconds, a sustained processing segment 902 runs fortwenty seconds. During segment 902, the rotating processing tool maycause liquid in the container to form an inverted substantially conicalshape on its surface due to the rotation of the liquid within thecontainer. That is, the liquid may be slightly higher along the outeredge of the container as compared to the inner portions.

By stopping (or significantly slowing) the rotation of the processingtool in an act 904, the liquid may settle such that the inverted conedisappears or decreases, and some or all of the solid foods within theliquid mixture may fall toward the bottom of the container. After theliquid has been allowed to calm for a suitable amount of time, forexample, 2.5 seconds in some embodiments, the processing tool isaccelerated quickly to rapidly jettison liquid outwardly toward thewalls of the containers as part of an act 906. The surge of liquidpushes up the inner walls of the container to reach upper areas thatwere not being contacted during the sustained processing of act 902. Inthis manner, food caught in the upper reaches of the container can bereturned to the liquid mixture for proper processing. For example, foodcaught on the upper side wall, and in some cases the underside of thecontainer lid, may be gathered with this stored sequence.

In the illustrated embodiment, act 906 includes a rapid acceleration,and the motor remains on for a total of 2.5 seconds. In otherembodiments, the processing tool may be rapidly accelerated and remainon for only 1.5 seconds, or any other suitable length of time. Or, insome embodiments, the processing tool may be accelerated over a periodof approximately three-quarters of a second, and the motor held on for atotal of at least four seconds or a significantly longer amount of time.

The rapid acceleration of the processing tool may be approximately atleast 2,500 rpm per second within a 72 oz. container holding 64 oz. ofliquefied food in some embodiments, and the top speed may be reachedwithin approximately 0.75 seconds of starting the motor. With a 5:1ratio transmission present, the motor may accelerate at 12,500 rpm persecond for the same container to accelerate the processing tool at 2,500rpm per second. In some embodiments, the speed attained after the rapidacceleration is approximately equal to the speed prior to the slowdownor stop, while in other embodiments, the speed attained after the rapidacceleration may be different from the speed prior to the slowdown orstop.

Other acts of starting the motor within the same sequence may include a“soft start” where the motor is not allowed to accelerate as quickly asit is capable of doing, while the act of rapidly accelerating theprocessing tool may not include a restriction on the acceleration. Insome embodiments, the food processing apparatus may be configured suchthat the food processing tool achieves an acceleration of at leastapproximately 3,400 rpm per second with a 72 oz. container holding 64oz. of liquefied food. In other embodiments the food processingapparatus may be configured to achieve an acceleration of at leastapproximately 2,000 rpm per second with a 72 oz. container holding 64oz. of liquefied food. In some embodiments, other acts of starting themotor within the same sequence and/or within other sequences may notinclude a “soft start”.

The sequence that sends liquid up the side wall can be preceded and/orfollowed by continuous processing acts (e.g., 10 seconds or more, 13seconds or more, or 20 seconds or more) in some embodiments so thatdesirable pulverization of the food items is achieved. Additionally, byincluding a relatively long, continuous processing act prior to a stepof propelling liquid up the side wall of the container, there is a highlikelihood that the processed ingredients will have been sufficientlyliquefied to allow the liquid surge to work. Though the amount of timerequired to liquefy the food ingredients can be dependent on the typeand quantity of food being processed. In some embodiments, a sensor maybe used to verify that sufficient liquefaction has been achieved priorto starting a sequence configured to propel liquid up the side wall. Insome embodiments, no verification or sensing of the liquid properties ofthe food ingredients is provided.

During a fountain effect sequence, instead of completely stopping themotor and processing tool, the motor may be significantly slowed. Forexample, in some embodiments, the motor may be slowed to 10% or less ofits prior speed to permit solid contents to settle and/or allow theliquid flow within the container to slow. Or the processing tool may beslowed to approximately 100 rpm or less to allow settling of contents.

According to another aspect, a sequence shown in flow chart 1000 of FIG.10 is particularly suited to process frozen food items. The sequenceincludes a series of six pulses where the motor runs for 1.5 seconds andthen stops for 2.5 seconds. A twenty second continuous run is followedby a three second pause, and then a 23 second continuous run. The timeperiod where the motor is off for three seconds and then followed by the23 second run may be a fountain effect sequence in some embodiments byhaving the motor accelerate quickly at the beginning of the 23 secondrun. In other embodiments, the overall sequence may not include afountain effect, and instead may have a slow start to the 23 second run.This frozen item blending sequence may be particularly effective whenused in combination with the blade assembly shown in FIGS. 29 and 30. Byincorporating a stopped portion between two extended run periods, largerpieces of food can fall back toward the bottom of the container and/ormove toward the middle of the container, allowing the larger pieces tobe chopped or otherwise processed by the blades or other processingtool.

According to another aspect of the disclosure, a specific sequence ofblending operations may be instituted to puree foods. For example, insome embodiments, a progression of faster speeds may be used to create apuree. A first and second speed may progress from low to medium to startprocessing the food, such as chickpeas. A third, high speed segment isrun after the low and medium segments. By starting at slower speeds, theblades initially break down the ingredients so that during the higherspeed phase, cavitation can be avoided. The higher speed purees theingredients quickly but starting immediately at high speed could resultin cavitation. In some embodiments, the high speed may be run for longerthan the low and medium speed times combined, such as shown in theembodiment of FIG. 11A with a flow chart 1100. In some cases, thesequence may be arranged so that a given steady-state speed is notslower than any preceding steady-state speed. A puree sequence such asthe one shown in FIG. 11A may be particularly useful in combination withthe blade arrangement shown and described with reference to FIG. 3. Insome embodiments, a puree sequence may include no stopping of the motorduring the sequence.

As shown in FIG. 11B with a flow chart 1150, the apparatus may beoperated at a low speed for a longer period of time than a high speed.For example, in the embodiment of FIG. 11B, the blades are rotated at afirst, low speed for fifteen seconds, then at a medium speed for tenseconds, and finally at a high speed for ten seconds. Such anarrangement may be helpful when the high speed segment is run at 1,300watts or below, in order to sufficiently process the ingredients duringthe low and medium segments to permit a desirable flow of ingredientsduring the high speed segment. A puree sequence such as the one shown inFIG. 11B may be particularly useful in combination with the bladearrangement shown and described with reference to FIG. 3. In someembodiments, the total time period of a low speed segment and a mediumspeed segment combined may exceed the time period of a high speedsegment. The low speed may be run with a motor power that would provide15,000 rpm unloaded—900 watts in some embodiments, or at anothersuitable power. The medium speed may be run with a motor power thatwould provide 20,000 rpm unloaded—1,200 watts in some embodiments, or atanother suitable power. And the high speed may be run with a motor powerthat would provide 21,500 rpm unloaded—1,275 watts in some embodiments,or at another suitable power.

FIG. 12 shows a flow chart 1200 of a sequence for pureeing food, where athird, high speed is run for longer than a first, low speed and asecond, medium speed combined. In this particular embodiment, the lowand medium speeds are operated for five seconds each, and the high speedis operated for fifty seconds. One or more of the low, medium, and highspeed segments may be run for longer than five seconds, five seconds,and fifty seconds respectively in some embodiments. In some embodiments,the low speed is run for at least four seconds, the medium speed is runfor at least four seconds, and the high speed is run for at least fortyseconds.

A puree sequence such as the one shown in FIG. 12 may be particularlyuseful in combination with the stacked blade arrangements shown anddescribed with reference to FIGS. 29 and 30 further below.

FIG. 13 shows a flow chart 1300 of a sequence for pureeing food, whereagain, a third, high speed is run for longer than a first, low speed anda second, medium speed combined. In this particular embodiment, the lowand medium speeds are operated for five seconds each, and the high speedis operated for sixty-five seconds. One or more of the low, medium, andhigh speed segments may be run for longer than five seconds, fiveseconds, and sixty-five seconds respectively in some embodiments. Insome embodiments, the low speed is run for at least four seconds, themedium speed is run for at least four seconds, and the high speed is runfor at least fifty-five seconds.

A puree sequence such as the one shown in FIG. 13 may be particularlyuseful in combination with the stacked blade arrangements shown anddescribed with reference to FIG. 32 further below.

A sequence configured for use with the blades and container shown inFIG. 3 is shown with a flow chart 1400 in FIG. 14. This sequence may beused to process frozen foods to produce a personal serving. A series offour pulses start the sequence, each being 1.5 seconds on and 2.5seconds off An act of powering the processing tool for twenty-twoseconds follows the pulses. The motor is then turned off for 2.5seconds, and then rapidly accelerated to provide a fountain effect. Oncethe motor is brought up to speed by the rapid acceleration, the motor ismaintained on for a total of 19.5 seconds. The motor may be powered forother periods of time, for example, at least eight seconds in someembodiments.

In some embodiments, the overall sequence may not include a fountaineffect sequence, and instead may have slow start to the 19.5 second run.The sequences associated with frozen food, such as the sequence shown inFIG. 14, may be used with processing assemblies and containers otherthan those shown in FIG. 3. The sequence of FIG. 3 (and variantsthereof) may be used with the blender base shown in FIG. 2, or, in someembodiments, may be used with the blender base shown in FIG. 1. Forexample, see FIG. 33 which shows a container similar to that of FIG. 3being used with the blender base of FIG. 1.

The blades and container shown in FIG. 3 may be used with the sequenceshown in flow chart 1500 in FIG. 15 to process fresh foods. The sequenceincludes two pulses of 1.5 seconds on and two seconds off, followed by atwelve second on period. A fountain effect sequence is then employed,with two seconds off, followed by a rapid acceleration. In someembodiments, the act of running the motor for twenty-four seconds afterthe two second pause may not include a rapid acceleration and mayinstead include an acceleration where the power to the motor isrestricted.

The illustrated sequence may be used with containers and/or processingtools other than the container and processing tool shown in FIG. 3 insome embodiments.

FIG. 16 shows a flow chart 1600 for one embodiment of a sequence that isparticularly suited for personal serving containers (e.g., see FIG. 3)when pureeing food items. The sequence includes fifteen seconds at a lowsetting, ten seconds at a medium setting, and ten seconds at a highsetting. The low setting may be run at a power which runs the motor atapproximately 15,000 rpm when unloaded (though more slowly when loaded).The medium setting may be run at a power which runs the motor atapproximately 20,000 rpm when unloaded, and the high setting may be runat a power which runs the motor at approximately 21,500 rpm whenunloaded.

A seventy second sequence is illustrated in flowchart 1700 in FIG. 17 asone embodiment which is particularly suited to crush ice as part ofprocessing ingredients in personal serving container, such as thecontainer shown in FIG. 3. This sequence includes two pulses followed byfive seconds on and 2.5 seconds off. Two more pulses are executed,followed by twenty seconds on, 2.5 seconds on, and then another pulse.The sequence concludes with twenty seconds of continuous run time. Eachof the segments may be run at 85% power in some embodiments.

FIGS. 18 and 19 illustrate sequences 1800 and 1900, respectively, thatmay be used for blending and, in some embodiments, blending in acontainer such as the container shown in FIG. 31. The seventy-secondsequence shown in flowchart 1800 begins with a series of three pulses,each being 2 seconds on and 2.5 seconds off. Following the pulses, themotor is rapidly accelerated and maintained on for 15 seconds. The motoris then turned off for 2.5 seconds, and then brought up to speed byrapid acceleration and maintained on for a total of 20 seconds. Themotor is again turned off for 2.5 seconds, and then brought up to speedby rapid acceleration and maintained on for a total of 16.5 seconds. Insome embodiments, the total time of all blending segments is at least51.5 seconds. In some embodiments, the total time of all blendingsegments is less than 52 seconds. The total time of all pauses may be atleast 12.5 seconds.

The thirty-five-second sequence illustrated in flowchart 1900 alsobegins with a series of three pulses, each being 2 seconds on and 2.5seconds off. Following the pulses, the motor is rapidly accelerated andmaintained on for 8 seconds. The motor is then turned off for 2.5seconds, and then brought up to speed by rapid acceleration andmaintained on for a total of 11 seconds. In such embodiments, the totaltime of all blending segments is at least 19 seconds, and the total timeof all pauses is at least 10 seconds. FIGS. 20 and 21 show sequences2000 and 2100, respectively, that may be used for extracting (e.g.,extracting nutrients) and, in some embodiments, extracting using apersonal serving container (see, e.g., FIG. 3). The seventy-secondsequence illustrated in flowchart 2000 begins with a series of twopulses, each being 1.5 seconds on and 2.5 seconds off. Following thepulses, the motor is rapidly accelerated and maintained on for a totalof 10 seconds, and then is turned off for 2.5 seconds. A pulse of 2seconds on and 2.5 seconds off follows. The motor is again rapidlyaccelerated and maintained on for a total of 20 seconds. The motor isturned off for 2.5 seconds and then brought up to speed by rapidacceleration and maintained on for a total of 22.5 seconds. In someembodiments, the total time of all blending segments is at least 52seconds and, in some embodiments, at least 52.5 seconds. The total timeof all pulses may be at least 12.5 second.

The forty-five-second sequence illustrated in flowchart 2100 also beginswith a series of two pulses, each 1.5 seconds on and 2.5 seconds off.The motor is then turned on for 5 seconds and then turned off for 2.5seconds. Next, the motor is brought up to speed rapidly and maintainedon for 13 seconds. The motor is then turned off for 2.5 seconds andrapidly accelerated and maintained on for 14 seconds. In such anembodiment, the total time of all blending segments is at least 32seconds, and the total time of all pulses is at least 10 seconds.

FIGS. 22 and 23 show sequences 2200 and 2300, respectively, for blendingand, in some embodiments, blending in a personal serving container (see,e.g., FIG. 3). The sixty-second sequence illustrated in flowchart 22begins with three pulses, each being 1.5 seconds on and 2.5 seconds off.A fourth pulse, being 2 seconds on and 2.5 second off, follows. Themotor is then rapidly accelerated and maintained on for a total of 25seconds. The motor is then turned off for 2.5 seconds and then broughtup to speed by rapid acceleration and maintained on for 16 seconds. Inthis embodiment, the total time of all blending segments is at least 41seconds, and the total time of all pulses is at least 12.5 seconds.

The forty-second sequence of flowchart 2300 also beings with threepulses, each being 1.5 seconds on and 2.5 seconds off. The motor is thenrapidly accelerated and maintained on for 8 seconds. The motor is thenturned off for 2.5 seconds, and then rapidly accelerated and maintainedon for 7.5 seconds. The motor is again turned off for 2.5 seconds, andthen brought up to speed by rapid acceleration and maintained on for 7.5second. In such an embodiment, the total time of all blending segmentsis at least 23 seconds, and the total time of all pulses is at least12.5 seconds.

FIGS. 24 and 25 show sequences 2400 and 2500, respectively, for blending(e.g., blending in the container shown in FIG. 31). Theseventy-five-second sequence illustrated in flowchart 2400 begins withthree pulses, each being 2 seconds on and 2.5 seconds off. Following thepulses, the motor is rapidly accelerated and maintained on for 9 secondsand is then turned off for 2.5 seconds. Two more pulses, each being 2seconds on and 2.5 seconds off, follow. The motor is then rapidlyaccelerated and maintained on for 20 seconds. The motor is then turnedoff for 2.5 seconds, and then brought to speed rapidly and maintained onfor 18.5 seconds. In some embodiments, the total time of blendingsegments is at least 47 segments, and in some embodiments at least 47.5seconds. The total time of all pulses may be at least 17.5 seconds.

The forty-second sequence of flowchart 2500 begins with four pulses thatare each 2 seconds on and 2.5 seconds off. Following the pulses, themotor is bought up to speed rapidly and maintained on for 8.5 seconds.The motor is then turned off for 2.5 seconds and then rapidlyaccelerated and maintained on for 11 seconds. In such an embodiment, thetotal time of all blending segments is at least 19.5 seconds, and thetotal time of all pulses is least 12.5 seconds.

FIG. 26 illustrates sequence 2600, which may be used for chopping (e.g.,chopping with the container shown in FIG. 31). This 40.9-second sequenceincludes fourteen pulses, each pulse being 0.3 seconds on and 2.6seconds off The motor is pulsed for a fifteenth time for 0.3 seconds on.In this embodiment, the total time of all blending segments is at least19.5 seconds, and the total time of all pulses is least 12.5 seconds.

In the embodiments shown in FIGS. 18-26, the motor may operate with a200 ms linear ramp from zero to full power during transitions from offto on, excepts during the pulses. In the embodiments illustrated inFIGS. 18-19 and 24-26, the motor may operate a high setting ofapproximately 4,000 rmp. The motor also may have a low setting ofapproximately 2,800 rpm. In the embodiments illustrated in FIGS. 20-23,the motor may operate at a high setting of approximately 20,000 rpm. Themotor also may have a low setting of approximately 12,000 rpm.

In the embodiments described, the time provided for the pulsing segmentsand blending segments may differ from those described. For example, thetimes may vary up to about 0.5 seconds for each of the stated ranges.

User-Alterable Program

A flowchart 2700 of a pulse control algorithm is shown in FIG. 27 as oneexample of a food processing sequence which can be altered by a userduring operation of the sequence. In an act 2702, the controller checksthat a container is engaged with the blender base via a sensor. Ifengaged, the controller checks whether a pulse switch is closed (i.e.,actuated) in an act 2704. The pulse switch may be closed by a userpressing a button in some embodiments, or in any other suitable manner.The term “switch”, for purposes herein, is intended to be construedbroadly, in the sense that any device or structure which receives a userinput and is capable of communicating the resulting state of the deviceto the controller should be considered to be a switch.

Once the pulse switch is closed, the motor is turned on for 0.25 secondsin an act 2706 in the illustrated embodiment. The motor is then shut offregardless of any further action taken by the user with respect to thepulse button during the 0.25 seconds that the motor is running. Afterthe 0.25 seconds of motor run time, if the pulse switch has beencontinuously closed (e.g., by the user continuously pressing the pulsebutton) throughout the 0.25 seconds, as checked in an act 2708, themotor remains off until one of two actions occurs. In a first scenario,if the pulse button continues to be pressed, that is, if the button isnot released from the time of its initial pressing, the motor willre-start 1.5 seconds after the initial 0.25 run time is completed, andrun for a second 0.25 second time period (act 2710). This stored 1.5second interval represents a default “off’ time. In a second scenario,if the pulse button is released at any time, and then re-pressed whilethe motor is off, a new 0.25 second motor run time is started at thetime of the re-pressing of the button. In this manner, in an act 2712,the motor remains off until the pulse switch is closed.

In this manner, the user is able to control the “off’ time during thepulsing routine, but the “on” time is not alterable by the user throughuse of the pulse button. In some embodiments, pressing an “off’ or“stop” button can stop the motor during a pulsing routine prior to theprogrammed stop time.

If the pulse button is continuously held, the motor will cycle throughthe stored on and off time periods until a stored number of cycles isreached in some embodiments. For example, in some embodiments, the motorwill turn on thirty times, with pauses between the run times, before thecontroller stops causing the motor to run.

A counter display may be included on the food processing apparatus insome embodiments to indicate to the user how many cycles (i.e., how manymotor activations) have occurred. Releasing the pulse button does notreset the counter in some embodiments. For example, if eight cycles havebeen run, and the user releases the pulse button to extend an off time,the number “8” will remain on the display and resume upward counting ifthe pulse button is again pressed. If, after the pulse button has beenreleased, the user presses a different sequence button or other buttonprior to re-pressing the pulse button, the display will stop displayingthe number of pulse cycles, and the next time the pulse button ispressed, the display counter will start at zero.

In some embodiments, the amount of time that the motor is on for eachpulse may be different than 0.25 seconds. For example, in someembodiments, it may be 0.20 seconds, or 0.50 seconds, or any othersuitable length of time. The default time may be different than 1.5seconds. In some embodiments, the default time may be 1.0 seconds or 2.0seconds, or any other suitable length of time.

The lengths of times (e.g., 0.25 seconds “on” and 1.5 seconds “off’) maybe based on values stored in a memory associated with the controller.For purposes herein, when a stored value is used twice—once in a firstinstance and once in a second instance, the stored value may beconsidered to be two values. For example, consider a configuration wherea first time period is described as being based on a first stored value,a second time period is described as being based on a second storedvalue, and both time periods are the same length of time. Even if theexact same stored value is referenced by the controller to set thelength of both time periods, for purposes herein, one may consider thattwo stored values exist.

In some embodiments, the user may alter the amount of time that acertain segment of an overall sequence lasts, and the user may make thisalteration during the operation of the sequence, or even during theoperation of the particular segment being altered. For example, thelength of a high speed segment may be extended by the user by pressing a“continue” or “extend” button (or other suitable input) while the highspeed segment is operating. This segment may be a portion of thesequence that is not at the end of the sequence in some embodiments.

Dual Coupler

FIG. 28 is a top view of base 100 for a food processing apparatusaccording to one embodiment of the present disclosure. The base 100includes a body having a first, inner drive coupler 2802 and a second,outer drive coupler 2804. The drive couplers 2802, 2804 can be driven bythe motor (not shown) within the base 100. A transmission system may beconfigured within the base 100 to rotate the first, inner drive couplerat a faster speed than the second, outer drive coupler 2804. A firstcontainer used with the blender base 100 may couple with only the first,inner drive coupler 2802. For example, a personal serving type ofcontainer as shown in FIG. 3 may couple with the inner driver coupler2802. A second container, e.g., the container 3102 shown in FIG. 31 orthe container 3202 shown in FIG. 32, may couple with only the second,outer drive coupler 2804. In this manner, processing tools can be drivenat different speeds by a motor operating at a single speed.

The first row of Table 1 below shows the rotational speeds at which themotor would operate for the low, medium, high, and pulse settings insome embodiments. Rows 2-4 show the rotational speeds of the processingtools in the identified container (again assuming that no food ispresent in the container). The reduced speeds of the processing tool inthe 72 oz. jar are a result of the outer drive coupler being geared downby a 5:1 ratio (see FIG. 28 and its associated description). The 7-upbowl container also couples with the outer drive coupler, andadditionally includes a 3:1 gear down within the container itself,resulting in an overall 15:1 gear down relative to the motor speed.

TABLE 1 Low Medium High Pulse Motor 15,000 rpm  20,000 rpm  24,000 rpm 24,000 rpm  72 oz. 3,000 rpm 4,000 rpm 4,800 rpm 4,800 rpm Container7-Cup Bowl 1,000 rpm 1,333 rpm 1,600 rpm 1,600 rpm Bowl in Bowl 1,000rpm 1,333 rpm 1,600 rpm 1,600 rpm

Table 2 shows the rotational speed of the processing tool (e.g., blades)in the personal serving container. There is no gearing down of the motorspeed to the blade speed in some embodiments, and therefore the motorspeed is the same as the blade speed. The power supplied to the motor atthe high setting may be 85% of rated power, thereby keeping the motorspeed and blade speed to approximately 21,500 rpm.

TABLE 2 Low Medium Hi2h Pulse Personal 15,000 rpm 20,000 rpm 21,500 rpm21,500 rpm Serving Container

Container Sensors

Also visible on the blender base 100 illustrated in FIG. 28 are threedepressible plungers 802 a, 802 b, and 802 c, some or all of which maybe used to sense the presence of a container on the blender base bybeing pressed by protrusions on the containers such that the plungerstrip a switch. In some embodiments, the plungers, or other sensors, maybe used to determine what type of container is mounted to the blenderbase.

For example, in one embodiment, one of plungers 802 a and 802 b isconfigured to be pressed by a protrusion on a 72 oz. container, such asthe one shown in FIG. 31, when the container is attached to the blenderbase 100. Which of the two plungers 802 a, 802 b is pressed when thecontainer is attached depends on the orientation of the container whenit is attached. In either of the two available orientations, eitherplunger 802 a or plunger 802 b is pressed. A plunger 802 c is notpressed when the 72 oz. container is attached to the blender base. Inthis embodiment, the controller may be configured to determine that the72 oz. container is attached when either of plungers 802 a or 802 b ispressed but plunger 802 c is not pressed.

When a food processing container, such as the one shown in FIG. 32, ismounted to blender base 100, plunger 802 c is pressed. One or both ofplungers 802 a and 802 b may additionally be pressed, but the controllermay be arranged to determine that the food processing container isattached when plunger 802 c is pressed.

To sense the presence of a personal serving container, a separatesensor, such as one or more depressible protrusions arranged to interactwith tabs of the personal serving container may be used. When a switchassociated with the depressible protrusion is triggered, the controllermay determine that the personal serving container is attached.

Depending on which type of container is sensed to be present on theblender base, one or more of the buttons may not be available for usedas a user input. For example, referring back to FIG. 1, button 118 mayonly be useable when the personal serving container is mounted to theblender base. When the personal serving container is mounted to thebase, an indicator light 132 illuminates to let the user know that thesequence associated by button 118 is available for use with the mountedcontainer. When a different type of container is mounted to blender base100, indicator light 132 does not illuminate, thereby indicating to theuser that that particular sequences is not available for use.

In some embodiments, the same button may be used to initiate differentsequences depending on which type of container is attached. For example,pressing button 116 may cause a puree sequence to start. However, when acontainer of the type shown in FIG. 31 is present, the puree sequenceinitiated by pressing button 116 may be the sequence illustrated in FIG.12, while the sequence illustrated in FIG. 13 may be initiated when acontainer of the type shown in FIG. 32 is mounted to blender base 100.In this manner, the food processing apparatus may permit one touchoperation in conjunction with selective use of two or more containers.In other embodiments, a user may press a separate start (button toinitiate operation) after pressing a button which selects a certainsequence.

Blade Embodiments

FIGS. 29 and 30 illustrate one embodiment of a blade assembly 2900. Asshown, the blade assembly 2900 has a shaft 2904 and a plurality ofblades 2906, and the blades 1806 are arranged in sets of blades whichare spaced apart along the length of the shaft 2904. In one illustrativeembodiment, the blade assembly includes three sets of blades 2906, butit should be recognized that in another embodiment, the blade assemblymay include a different number of sets of blades, for example one set,two sets, or four or more sets. In some embodiments, instead of sets oftwo blades, sets of blades with different numbers of blades (e.g., threeor four blades per set) may be used. The blades 2906 may be removablyattached to the shaft 2904 or permanently attached to the shaft 2904.For purposes herein, a set of blades is intended to mean two or moreblades which are associated with each other in a manner other than beingattached to the same shaft. For example, a set of blades may include twoblades which have been cut from the same blank and attached to the shaftsuch that the two blades are made from a single piece of material andremain connect around the outside of the shaft. Or, in another example,a set of blades may include three blades which extend radially outwardlyfrom the shaft in the different directions, but each at approximatelythe same vertical location on the shaft. In another example, a set ofblades may include two blades extending radially outwardly from theshaft in the same direction but spaced vertically from one anotherwithout any other blades between the two blades. In yet another example,a set of blades may include two blades which extend outwardly from theshaft in opposite directions and located more closely with each otherthan with another blade on the shaft.

A first end 2902 of the blade assembly 2900 is configured to engage withthe lid. More specifically, as shown, the first end 2902 of the bladeassembly may include a pin or other protruding component configured tobe inserted into a bushing (not shown) located on an underside of acontainer lid (see FIG. 31). It should be appreciated that the inventionis not limited in this respect, and for example, in another embodiment,the first end 2902 of the blade assembly 2900 may include a recesscomponent engageable with a protruding component on the lid, and/or thesecond end 2908 of the blade assembly 2900 may include a protrudingcomponent that is engageable with a recessed component on the container.

As shown in FIG. 30, a second end 2908 of the blade assembly may beconfigured to engage with a container. In this particular embodiment,the second end 2908 of the blade assembly includes a cavity that isconfigured to engage with a spindle (not shown) in the container. Asshown, the second end 2908 of the blade assembly 2900 may include apattern, such as a star-shaped pattern which engages with the shape ofthe spindle. Although a star-shaped pattern is illustrated, otherconfigurations are also contemplated, such as, but not limited to,circular, triangular, square, rectangular, or hexagonal patterns.

It should be recognized that the blade assembly 2900 shown in FIGS. 29and 30 may be used for various applications, such as, but not limited tocutting, slicing, dicing, and pureeing food within the container. In theillustrated embodiment, the blades 2906 have sharp leading edges whichare rearwardly curved relative to the direction of rotation.

Container Embodiments

A 72 oz. container 3102 with an attached lid 3104 is shown mounted toblender base 100 in FIG. 31. A blade assembly 2900 similar to the bladeassembly illustrated in FIGS. 29 and 30 is positioned within thecontainer. Other sizes of containers may be used in various embodiments.Other blade arrangements or other processing tools may be used withcontainers that are mounted to blender base 100. In some embodiments,blade assemblies which include transmissions positioned within thecontainer itself may be used in conjunction with blender base 100 andstored sequences that are used to operate the food processing apparatus.

FIG. 32 shows one illustrative embodiment of a food processing container3202 which has blade assembly 3204 with two pairs of blades 3206, 3208.The food processing container may have a volume of approximately 56 oz.in some embodiments, though any suitable size may be used. A lid 3210,which may be lockable to the container in some embodiments, is alsoprovided. As mentioned above, a transmission (not shown), such as aplanetary gear assembly, may positioned underneath the container suchthat driving a driven coupler results in a slower rotational speed, buthigher torque, of the processing tool as compared to the drive coupler.

FIG. 33 shows one embodiment of a personal serving container 3302mounted to blender base 100. The container and blade assembly may besimilar to the container and blade assembly shown in FIG. 3. In someembodiments, personal serving container 3302 may have a volume of 18oz., while other embodiments may include a personal serving containerwith a volume of 24 oz. or 32 oz.

Controller

FIG. 34 is a block diagram of an illustrative embodiment of a computersystem 3400 that may be used in one or more of the food processingapparatuses disclosed herein or used to perform one or more of themethods described herein, e.g., as a controller. Computer system 3400may include one or more processors 3410 and one or more non-transitorycomputer-readable storage media (e.g., memory 3420 and/or one or morestorage media 3430). The processor 3410 may control writing data to andreading data from the memory 3420 and the non-volatile storage device3430 in any suitable manner, as the aspects of the invention describedherein are not limited in this respect. The computer system 3400 alsomay include a volatile storage media.

To perform functionality and/or methods described herein, the processor3410 may execute one or more instructions stored in one or morecomputer-readable storage media (e.g., the memory 3420, storage media,etc.), which may serve as non-transitory computer-readable storage mediastoring instructions for execution by the processor 3410. Computersystem 3400 also may include any other processor, controller or controlunit needed to route data, perform computations, perform I/Ofunctionality, etc. For example, computer system 2500 may include anynumber and type of input functionality to receive data and/or mayinclude any number and type of output functionality to provide dataand/or audio and/or visual feedback to a user, and may include controlapparatus to operate any present I/O functionality.

In connection with the food processing sequences and other foodprocessing control described herein, one or more programs configured toreceive user input(s), receive signals from one or more sensors,evaluate inputs, set run times and/or run speeds, and/or providefeedback and/or information to user may be stored on one or morecomputer-readable storage media of computer system 3400. Processor 3410may execute any one or combination of such programs that are availableto the processor by being stored locally on computer system 2500 oraccessible over a network. Any other software, programs or instructionsdescribed herein may also be stored and executed by computer system3400. Computer 3400 may be a standalone computer, server, part of adistributed computing system, mobile device, etc., and may be connectedto a network and capable of accessing resources over the network and/orcommunicate with one or more other computers connected to the network.

Implementation of some of the techniques described herein using acomputer system (such as computer 2500) is an integral component ofpracticing these techniques, as aspects of these techniques cannot berealized absent computer implementation. At least part of the inventors'insight is derived from the recognition that control of food processorsin certain manners described herein can only be implemented using acomputer system.

The terms “program” or “software” are used herein in a generic sense torefer to any type of computer code or set of processor-executableinstructions that can be employed to program a computer or otherprocessor to implement various aspects of embodiments as discussedabove. Additionally, it should be appreciated that according to oneaspect, one or more computer programs which, when executed performmethods of the disclosure provided herein, need not reside on a singlecomputer or processor, but may be distributed in a modular fashion amongdifferent computers or processors to implement various aspects of thetechnology described herein.

Processor-executable instructions may be in many forms, such as programmodules, executed by one or more computers or other devices. Generally,program modules include routines, programs, objects, components, datastructures, etc. that perform particular tasks or implement particularabstract data types. Typically, the functionality of the program modulesmay be combined or distributed as desired in various embodiments. Also,data structures may be stored in one or more non-transitorycomputer-readable storage media in any suitable form.

According to some embodiments, a user interface and/or controller may bepartially or completely present on a wireless device which is physicallyseparate from the food processing apparatus yet be considered as being acomponent of the apparatus. In some embodiments, all or a portion of theuser interface may utilize a touchscreen interface or soft keys. Otherexamples of inputs for user interfaces include dials, switches, rotaryknobs, slide knobs, voice-activated commands, virtual keyboards, or anyother suitable input.

As used herein, the terms “connected,” “attached,” or “coupled” are notlimited to a direct connection, attachment, or coupling, as twocomponents may be connected, attached, or coupled to one another viaintermediate components.

The above described components may be made with various materials, asthe invention is not necessarily so limited.

The above aspects may be employed in any suitable combination, as thepresent invention is not limited in this respect. Additionally, any orall of the above aspects may be employed in a food processing apparatus;however, the present invention is not limited in this respect, as theabove aspects may be employed to process materials other than food.

Having thus described several aspects of at least one embodiment of thisinvention, it is to be appreciated that various alterations,modifications, and improvements will readily occur to those skilled inthe art. Such alterations, modifications, and improvements are intendedto be part of this disclosure and are intended to be within the spiritand scope of the invention. Accordingly, the foregoing description anddrawings are by way of example only.

What is claimed is:
 1. A food processing apparatus comprising: acontainer including at least one rotatable blade; a drive unit having adrive coupler to rotate the at least one blade; a controller to controlthe drive unit; and at least one non-transitory memory storingprocessor-executable instructions that, when executed by the controller,cause the controller, in response to a first user input, tosequentially: activate the drive unit for three seconds or less torotate the drive coupler as a first pulse; pause the drive unit for atleast one second; activate the drive unit for three seconds or less torotate the drive coupler as a second pulse; pause the drive unit for atleast one second; activate the drive unit for at least five seconds torotate the drive coupler as a first blending segment; pause the driveunit for at least one second; activate the drive unit for at least fiveseconds to rotate the drive coupler as a second blending segment; pausethe drive unit for at least one second; and activate the drive unit forat least five seconds to rotate the drive coupler as a third blendingsegment; wherein a total time period of all activations of the driveunit that are at least five seconds for blending segments is at leasttwenty-three seconds.
 2. The food processing apparatus as in claim 1,wherein the processor-executable instructions, when executed by thecontroller, cause the controller to activate the drive unit for threeseconds or less to rotate the drive coupler as a third pulse and pausethe drive unit for at least one second after the second pause and beforethe first blending segment.
 3. The food processing apparatus as in claim1, wherein a total time period of all activations of the drive unit thatare at least five seconds are less than about fifty-two seconds.
 4. Thefood processing apparatus as in claim 1, wherein a total time period ofall pauses of the drive unit is at least ten seconds.
 5. The foodprocessing apparatus as in claim 1, wherein the activation of the driveunit for the first blending segment has a shorter length of time thanthe activation of the drive unit for each of the second and thirdblending segments.
 6. The food processing apparatus as in claim 1,wherein the activation of the drive unit for the first blending segmentlasts longer than the activation of the drive unit for each of thesecond and third blending segments.
 7. The food processing apparatus asin claim 2, wherein the activation of the drive unit for the firstblending segment is at least fifteen seconds, the activation of thedrive unit for the second blending segment is at least twenty seconds,and the activation of the drive unit for the third blending segment isat least 16.5 seconds.
 8. The food processing apparatus as in claim 7,wherein a total time period from a first activation of the drive unituntil a last activation of the drive unit is seventy seconds or less. 9.The food processing apparatus as in claim 2, wherein the activation ofthe drive unit for the first blending segment is at least eight seconds,the activation of the drive unit for the second blending segment is atleast 7.5 seconds, and the activation of the drive unit for the thirdblending segment is at least 7.5 seconds.
 10. The food processingapparatus as in claim 9, wherein a total time period from a firstactivation of the drive unit until a last activation of the drive unitis forty seconds or less.
 11. The food processing apparatus as in claim1, wherein the activation of the drive unit for the first blendingsegment is at least five seconds, the activation of the drive unit forthe second blending segment is at least thirteen seconds, and theactivation of the drive unit for the third blending segment is at leastfourteen seconds.
 12. The food processing apparatus as in claim 11,wherein a total time period from a first activation of the drive unituntil a last activation of the drive unit is forty-five seconds or less.13. A food processing apparatus comprising: a container including atleast one rotatable blade; a drive unit having a drive coupler to rotatethe at least one blade; a controller to control the drive unit; and atleast one non-transitory memory storing processor-executableinstructions that, when executed by the controller, cause thecontroller, in response to a first user input, to sequentially: activatethe drive unit for three seconds or less to rotate the drive coupler asa first pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa second pulse; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa third pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa first blending segment; pause the drive unit for at least one second;and activate the drive unit for at least five seconds to rotate thedrive coupler as a second blending segment; wherein a total time periodof all activations of the drive unit that are at least five seconds forblending segments is at least nineteen seconds.
 14. The food processingapparatus as in claim 13, wherein the activation of the drive unit forthe first blending segment is at least eight seconds and the activationof the drive unit for the second blending segment is at least elevenseconds.
 15. The food processing apparatus as in claim 14, wherein atotal time period from a first activation of the drive unit until a lastactivation of the drive unit is thirty-five seconds or less.
 16. Thefood processing apparatus as in claim 13, wherein theprocessor-executable instructions, when executed by the controller,cause the controller to activate the drive unit for three seconds orless to rotate the drive coupler as a fourth pulse and pause the driveunit for at least one second at a time after the third pause and beforethe first blending segment.
 17. The food processing apparatus of claim16, wherein the activation of the drive unit for the first blendingsegment is at least 8.5 seconds and the activation of the drive unit forthe second blending segment is at least eleven seconds.
 18. The foodprocessing apparatus as in claim 17, wherein a total time period from afirst activation of the drive unit until a last activation of the driveunit is forty seconds or less.
 19. The food processing apparatus ofclaim 16, wherein the activation of the drive unit for the firstblending segment is at least twenty-five seconds and the activation ofthe drive unit for the second blending segment is at least sixteenseconds.
 20. The food processing apparatus as in claim 19, wherein atotal time period from a first activation of the drive unit until a lastactivation of the drive unit is sixty seconds or less.
 21. A foodprocessing apparatus comprising: a container including at least onerotatable blade; a drive unit having a drive coupler to rotate the atleast one blade; a controller to control the drive unit; and at leastone non-transitory memory storing processor-executable instructionsthat, when executed by the controller, cause the controller, in responseto a first user input, to sequentially: activate the drive unit forthree seconds or less to rotate the drive coupler as a first pulse;pause the drive unit for at least one second; activate the drive unitfor three seconds or less to rotate the drive coupler as a second pulse;pause the drive unit for at least one second; activate the drive unitfor at least five seconds to rotate the drive coupler as a firstblending segment; pause the drive unit for at least one second; activatethe drive unit for three seconds or less to rotate the drive coupler asa third pulse; pause the drive unit for at least one second; activatethe drive unit for at least five seconds to rotate the drive coupler asa second blending segment; pause the drive unit for at least one second;and activate the drive unit for at least five seconds to rotate thedrive coupler as a third blending segment; wherein a total time periodof all activations of the drive unit that are at least five seconds forblending segments is at least fifty-two seconds.
 22. The food processingapparatus as in claim 21, wherein the activation of the drive unit forthe first blending segment is at least ten seconds, the activation ofthe drive unit for the second blending segment is at least twentyseconds, and the activation of the drive unit for the third blendingsegment is at least 22.5 seconds.
 23. The food processing apparatus asin claim 22, wherein a total time period from a first activation of thedrive unit until a last activation of the drive unit is seventy secondsor less.
 24. A food processing apparatus comprising: a containerincluding at least one rotatable blade; a drive unit having a drivecoupler to rotate the at least one blade; a controller to control thedrive unit; and at least one non-transitory memory storingprocessor-executable instructions that, when executed by the controller,cause the controller, in response to a first user input, tosequentially: activate the drive unit for three seconds or less torotate the drive coupler as a first pulse; pause the drive unit for atleast one second; activate the drive unit for three seconds or less torotate the drive coupler as a second pulse; pause the drive unit for atleast one second; activate the drive unit for three seconds or less torotate the drive coupler as a third pulse; pause the drive unit for atleast one second; activate the drive unit for at least five seconds torotate the drive coupler as a first blending segment; pause the driveunit for at least one second; activate the drive unit for three secondsor less to rotate the drive coupler as a fourth pulse; pause the driveunit for at least one second; activate the drive unit for three secondsor less to rotate the drive coupler as a fifth pulse; pause the driveunit for at least one second; activate the drive unit for at least fiveseconds to rotate the drive coupler as a second blending segment; pausethe drive unit for at least one second; and activate the drive unit forat least five seconds to rotate the drive coupler as a third blendingsegment; wherein a total time period of all activations of the driveunit that are at least five seconds for blending segments is at leastforty-seven seconds.
 25. A food processing apparatus as in claim 24,wherein the activation of the drive unit for the first blending segmentis at least nine seconds, the activation of the drive unit for thesecond blending segment is at least twenty seconds, and the activationof the drive unit for the third blending segment is at least 18.5seconds.
 26. The food processing apparatus as in claim 24, wherein atotal time period from a first activation of the drive unit until a lastactivation of the drive unit is seventy-five seconds or less.
 27. Amethod used in connection with operation of a food processing apparatus,the apparatus comprising a drive unit to drive a food processingassembly, a controller to control the drive unit, and at least onenon-transitory memory storing processor-executable instructions that areexecutable by the controller to cause the controller to control thedrive unit, the method comprising: in response to a first user input,sequentially: activating the drive unit for three seconds or less torotate the drive coupler as a first pulse; pausing the drive unit for atleast one second; activating the drive unit for three seconds or less torotate the drive coupler as a second pulse; pausing the drive unit forat least one second; activating the drive unit for at least five secondsto rotate the drive coupler as a first blending segment; pausing thedrive unit for at least one second; activating the drive unit for atleast five seconds to rotate the drive coupler as a second blendingsegment; pausing the drive unit for at least one second; and activatingthe drive unit for at least five seconds to rotate the drive coupler asa third blending segment; wherein a total time period of all activatingof the drive unit for at least five seconds for blending segments is atleast twenty-three seconds.